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Electrorotation of Deformable Fluid Droplets

✍ Scribed by Sonja Krause; Preeti Chandratreya

Publisher
Elsevier Science
Year
1998
Tongue
English
Weight
413 KB
Volume
206
Category
Article
ISSN
0021-9797

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✦ Synopsis

An equilibrium phase separated ternary system of polystyrene (PS)/polydimethylsiloxane (PDMS)/p-xylene was prepared, and the PS-rich phase was dispersed as droplets in a matrix of the PDMS-rich phase. The system was placed between vertical electrodes and the droplets rotated around a vertical axis perpendicular to the electric field direction in 4 -8-kV cm ؊1 DC fields; in 2-4-kV cm ؊1 , 0.1-Hz AC fields; and in 4-kV cm ؊1 , 1-MHz AC fields, in some cases stopping, restarting, and changing the direction of rotation. They rotated less than a quarter of a turn back and forth in 1-10-Hz, 2-4-kV cm ؊1 fields and did not rotate at all in 1-kHz fields. Rotational velocities measured in the DC field were in agreement with an existing theory; those measured in the 0.1-Hz AC field and estimated in the 1-MHz AC field were in direct disagreement with a different existing theoretical treatment. When the PDMS-rich droplets were dispersed into a matrix of the PS-rich phase, the droplets elongated in the field direction in a 2-kV/cm, 0.1-Hz electric field. Occasionally a portion of the matrix phase broke off into the PDMS-rich droplet, rotated for a while, and then rejoined the matrix phase.

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